Design of process and control scheme for cyclohexanol production from cyclohexene using reactive distillation

doi:10.1016/j.cjche.2020.11.029

Chinese Journal of Chemical Engineering ›› 2021, Vol. 40 ›› Issue (12): 96-105.DOI: 10.1016/j.cjche.2020.11.029

• Separation Science and Engineering • Previous Articles Next Articles

Design of process and control scheme for cyclohexanol production from cyclohexene using reactive distillation

Mingyuan Hu¹, Hui Tian^1,2

1. College of Chemistry and Chemical Engineering, Yantai University, Yantai 264005, China;
2. Collaborative Innovation Center of Comprehensive Utilization of Light Hydrocarbon Resource, Yantai University, Yantai 264005, China

Received:2020-07-22 Revised:2020-11-16 Online:2022-01-14 Published:2021-12-28
Contact: Hui Tian,E-mail:tianhui@ytu.edu.cn
Supported by:
The authors acknowledge the Natural Science Foundation of Shandong Province, China (ZR2017QB006), the Focus on Research and Development Plan in Yantai city (2018XSCC038), and the Qingchuang Science and Technology Plan Innovation Team of Shandong Province (2019KJC012).

Design of process and control scheme for cyclohexanol production from cyclohexene using reactive distillation

Mingyuan Hu¹, Hui Tian^1,2

1. College of Chemistry and Chemical Engineering, Yantai University, Yantai 264005, China;
2. Collaborative Innovation Center of Comprehensive Utilization of Light Hydrocarbon Resource, Yantai University, Yantai 264005, China

通讯作者: Hui Tian,E-mail:tianhui@ytu.edu.cn
基金资助:
The authors acknowledge the Natural Science Foundation of Shandong Province, China (ZR2017QB006), the Focus on Research and Development Plan in Yantai city (2018XSCC038), and the Qingchuang Science and Technology Plan Innovation Team of Shandong Province (2019KJC012).

Abstract

Abstract: Cyclohexanol is a commonly used organic compound. Currently, the most promising industrial process for synthesizing cyclohexanol, by cyclohexene hydration, suffers from a low conversion rate and difficult separation. In this paper, a three-column process for catalytic distillation applicable in the hydration of cyclohexene to cyclohexanol was established to solve these. Simulation with Aspen Plus shows that the process has good advantages, the conversion of cyclohexene reached 99.3%, and the product purity was ≥99.2%. The stable operation of the distillation system requires a good control scheme. The design of the control scheme is very important. However, at present, the reactive distillation process for cyclohexene hydration is under investigation experimentally and by steady-state simulation. Therefore, three different plant-wide control schemes were established (CS1, CS2, CS3) and the position of temperature sensitive stage was selected by using sensitivity analysis method and singular value decomposition method. The Tyreus-Luyben empirical tuning method was used to tune the controller parameters. Finally, Aspen Dynamics simulation software was used to evaluate the performance of the three control schemes. By introducing ΔF ±20% and x_ENE ±5%, comparison the changes in product purity and yield of the three different control schemes. By comparison, we can see that the control scheme CS3 has the best performance.

Key words: Cyclohexene hydration, Catalytic distillation, Control schemes, Dynamic Simulation

摘要： Cyclohexanol is a commonly used organic compound. Currently, the most promising industrial process for synthesizing cyclohexanol, by cyclohexene hydration, suffers from a low conversion rate and difficult separation. In this paper, a three-column process for catalytic distillation applicable in the hydration of cyclohexene to cyclohexanol was established to solve these. Simulation with Aspen Plus shows that the process has good advantages, the conversion of cyclohexene reached 99.3%, and the product purity was ≥99.2%. The stable operation of the distillation system requires a good control scheme. The design of the control scheme is very important. However, at present, the reactive distillation process for cyclohexene hydration is under investigation experimentally and by steady-state simulation. Therefore, three different plant-wide control schemes were established (CS1, CS2, CS3) and the position of temperature sensitive stage was selected by using sensitivity analysis method and singular value decomposition method. The Tyreus-Luyben empirical tuning method was used to tune the controller parameters. Finally, Aspen Dynamics simulation software was used to evaluate the performance of the three control schemes. By introducing ΔF ±20% and x_ENE ±5%, comparison the changes in product purity and yield of the three different control schemes. By comparison, we can see that the control scheme CS3 has the best performance.

关键词: Cyclohexene hydration, Catalytic distillation, Control schemes, Dynamic Simulation

Mingyuan Hu, Hui Tian. Design of process and control scheme for cyclohexanol production from cyclohexene using reactive distillation[J]. Chinese Journal of Chemical Engineering, 2021, 40(12): 96-105.

Mingyuan Hu, Hui Tian. Design of process and control scheme for cyclohexanol production from cyclohexene using reactive distillation[J]. 中国化学工程学报, 2021, 40(12): 96-105.

References

[1] N. Mahata, K. V. Raghavan, V. Vishwanathan, et al., Phenol hydrogenation over palladium supported on magnesia: relationship between catalyst structure and performance, Phys. Chem. Chem. Phys, 3(13) (2001) 2712-2719
[2] N. Mahata, K. V. Raghavan, V. Vishwanathan, et al., Influence of the charge transfer capacity of alkali and alkaline earth metals as promoters in the hydrogenation of phenol over palladium and nickel catalysts, React. Kinet. Catal. L, 72(2) (2001) 297-302
[3] N. Mahata, V. Vishwanathan, Influence of Palladium Precursors on Structural Properties and Phenol Hydrogenation Characteristics of Supported Palladium Catalysts, J. Catal, 196(2) (2000) 262-270
[4] S. G. Shore, E. Ding, C. Park, et al., Vapor phase hydrogenation of phenol over silica supported Pd and Pd Yb catalysts, Catal. Commun, 3(2) (2002) 77-84
[5] K. V. R. Chary, D. Naresh, V. Vishwanathan, et al. Vapor phase hydrogenation of phenol over Pd/C catalysts: A relationship between dispersion, metal area and hydrogenation activity, Catal. Commun, 8(3) (2007) 471-477
[6] Y. Z. Xiang, X. N. Li, Liquid phase in-situ hydrogenation of phenol for synthesis of cyclohexanone and cyclohexanol, J. Chem. Ind. Eng, 58(12) (2007) 3041-3045
[7] L. F. Zhang, C. Y. Chen, Z. J. Xiang, Progress in Oxidation of Cyclohexane to Cyclohexanone and Cyclohexanol, J. B. Univ. Chem. Technol. (Nat Scied), 12(2) (2004) 39-43
[8] X. G. Wu, H. M. Liu, Study Progress and Technology of Oxidation Cyclohexane to Cyclohexanone, Science & Technology in Chemical Industry (China), 10(2) (2002) 48-53
[9] I. Sokmen, F. Sevin, Oxidation of cyclohexane catalyzed by metal-ion-exchanged zeolites, J. Colloid. Interf. Sci, 264(1) (2003) 208-211
[10] L. Zhou, J. Xu, H. Miao, et al., Catalytic oxidation of cyclohexane to cyclohexanol and cyclohexanone over Co₃O₄ nanocrystals with molecular oxygen, Appl. Catal. A-Gen, 292 (2005) 223-228
[11] T. Qiu, C. H. Kuang, C. G. Li, et al., Study on feasibility of reactive distillation process for the direct hydration of cyclohexene to cyclohexanol using a cosolvent, Ind. Eng. Chem. Res, 52(24) (2013) 8139-8148
[12] F. Steyer, H. Freund, K. Sundamcher, A novel reactive distillation process for the indirect hydration of cyclohexene using a reactive entrainer, Ind. Eng. Chem. Res, 47(23) (2008) 9581–9587
[13] M. Misono, T. Inui, New catalytic technologies in Japan, Catal. Today, 51(3) (1999) 369-375
[14] F. Hiroshi, M. Fujinao, K. Masao, Preparation of cycloalkanols by catalytic hydration of cycloalkenes, Japan Pat., 02040334, 1990.
[15] B. C. Chen, B. Y. Yu, Y. L. Lin, et al. Reactive-Distillation Process for Direct Hydration of Cyclohexene to Produce Cyclohexanol, Ind. Eng. Chem. Res, 53(17) (2014) 7079-7086
[16] R. Taylor, R. Krishna, Modeling reactive distillation, Chem. Eng. Sci, 55(22) (2000) 5183-5229
[17] J. S. Liu, P. Bai, S. Q. Zhu, er al., Prospect of research on reactive distillation process, Chemical Industry and Engineering (China), 19(1) (2002) 101-106
[18] B. D. Tyreus, W. L. Luyben., Controlling heat integrated distillation columns, Chem. Eng. Prog, 72(9) (1976) 59-66
[19] M. G. Sneesby, M. O. Tadé, T. N. Smith, A multi-objective control scheme for an ETBE reactive distillation column, Chem. Eng. Res. Des, 78(2) (2000) 283-292
[20] M. Al-Arfaj, W. L. Luyben, Comparison of alternative control structures for an ideal two-product reactive distillation column, Ind. Eng. Chem. Res, 39(9) (2000) 3298-3307
[21] Y. C. Tian, F. Zhao, B. H. Bisowarno, et al., Pattern-based predictive control for ETBE reactive distillation, J. Process. Contr, 13(1) (2003) 57-67
[22] Y. Takamatsu, T. Kaneshima, Process for the preparation of cyclohexanol, U.S. Patent, 0018223A1, 2003.
[23] H. Tian, J. C. Sun, Y. P. Du, and W, Y. Xu, Vapor-Liquid Phase Equilibrium of a Cyclohexene + Water + Cyclohexanol + Isophorone Quaternary System at 500 kPa, J. Chem. Eng. Data, 63 (2018) 4020-4023
[24] F. Steyer, K. Sundmacher, VLE and LLE Data Set for the System Cyclohexane + Cyclohexene + Water + Cyclohexanol + Formic Acid + Formic Acid Cyclohexyl Ester, J. Chem. Eng. Data, 50(4) (2005) 1277-1282
[25] Y. R. Wei, Estimation of vapor-liquid equilibrium data for two binary systems of isophorone-water and Mesityloxide-water at 1 atm, Jihua Technology (China), 4 (1) (1996) 22-25
[26] J. C. Sun. Measurement of Basal Data and Process Optimization of Cyclohexanol Produced by Catalytic Distillation, Thesis, Shandong: YanTai Univ., 2019
[27] M. M. Lin. Feasibility analysis and process simulation of reactive distillation of cyclohexene hydration, Thesis, Fuzhou Univ., 2016
[28] I. L. Chien, K.L. Zeng, H.Y. Chao, J.H. Liu, Design and control of acetic acidde hydration system via heterogeneous azeotropic distillation, Chem. Eng. Sci, 59 (2004) 4547–4567
[29] A. Muhammad, M. Al-Arfaj, L. William, Luyben., Comparative control study of ideal and methyl acetate reactive distillation, Chem. Eng. Sci, 57 (2002) 5039–5050
[30] C F. Moore, Selection of controlled and manipulated variables, chapter 8 in practical distillation control, New York: Van Nostrand Reinhold, 1992
[31] L. William, Luyben., Distillation design and control using Aspen simulation (Second Edition), US: John Wiley & Sons, 1992
[32] H. P. Huang, J. C. Jeng, C. H. Chiang, et al., A direct method for multi-loop PI/PID controller design, J. Process. Contr, 13 (2003): 769–786
[33] G. Abdulwahab, O. G. Saidat, Dynamics and Tyreus-Luyben tuned control of a fatty acid methyl ester reactive distillation process, Int. J. Eng. Sci, 3(5) (2015) 799-808

Design of process and control scheme for cyclohexanol production from cyclohexene using reactive distillation

Design of process and control scheme for cyclohexanol production from cyclohexene using reactive distillation

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	Jindong Dai, Chi Zhai, Jiali Ai, Guangren Yu, Haichao Lv, Wei Sun, Yongzhong Liu. A cellular automata framework for porous electrode reconstruction and reaction-diffusion simulation [J]. Chinese Journal of Chemical Engineering, 2023, 60(8): 262-274.
[2]	Zhiwei Wang, Yu Zhang, Zhi Zhang, Daowei Zhou, Zhikai Cao, Yong Sha. Investigation on catalytic distillation for ethyl acetate production with different catalytic packing structures [J]. Chinese Journal of Chemical Engineering, 2023, 53(1): 63-72.
[3]	Anshi Hong, Zisheng Zhang, Xingang Li, Xin Gao. A generalized CFD model for evaluating catalytic separation process in structured porous materials [J]. Chinese Journal of Chemical Engineering, 2022, 51(11): 168-177.
[4]	Jianglong Du, Haolan Tao, Jie Yang, Cheng Lian, Sen Lin, Honglai Liu. Understanding electrokinetic thermodynamics in nanochannels [J]. Chinese Journal of Chemical Engineering, 2021, 29(3): 33-41.
[5]	Mohammad El Wali, Saeed Rahimpour Golroudbary, Andrzej Kraslawski. Impact of recycling improvement on the life cycle of phosphorus [J]. Chinese Journal of Chemical Engineering, 2019, 27(5): 1219-1229.
[6]	Xiaohui Wang, Jiachen Li, Li Zhang. Understanding self-accelerated water diffusion within poly-lactic acid via molecular dynamics simulation [J]. Chinese Journal of Chemical Engineering, 2019, 27(4): 759-764.
[7]	Zhixian Huang, Yixiong Lin, Xiaoda Wang, Changshen Ye, Ling Li. Optimization and control of a reactive distillation process for the synthesis of dimethyl carbonate [J]. , 2017, 25(8): 1079-1090.
[8]	Cuimei Bo, Jun Li, Lei Yang, Hui Yi, Jihai Tang, Xu Qiao. MPC of distillation column with side reactors for methyl acetate [J]. Chin.J.Chem.Eng., 2017, 25(12): 1798-1804.
[9]	Yunhu Gao, Zhihong Xu, Kejing Wu, Xiaolu Wang, Zhaojun Yu, Weiyang Fei. The steady-state and dynamic simulation of cascade distillation system for the production of oxygen-18 isotope from water [J]. , 2016, 24(8): 979-988.
[10]	Lili Tao, ZhihuaHu, Feng Qian. Design and control of a p-xylene oxidation process [J]. Chin.J.Chem.Eng., 2015, 23(12): 1935-1944.
[11]	Muhammad Umar, Yahia Abubakar Al-Hamed, Abdulraheem Al-Zahrani, Hisham Saeed Bamufleh. Optimizing the Synthesis of Ethyl tert-Butyl Ether in Continuous Catalytic Distillation Column Using New Ion Exchange Resin Catalyst [J]. Chin.J.Chem.Eng., 2013, 21(10): 1121-1128.
[12]	BO Cuimei, TANG Jihai, BAI Yangjin, QIAO Xu, DING Lianghui, ZHANG Shi. The Design and Control of Distillation Column with Side Reactors for Chlorobenzene Production^* [J]. Chin.J.Chem.Eng., 2012, 20(6): 1113-1120.
[13]	LI Chengfei. Dynamic Simulation and Analysis of Industrial Purified Terephthalic Acid Solvent Dehydration Process [J]. , 2011, 19(1): 89-96.
[14]	YU Zhaosheng, SHAO Xueming, R.Tanner. Dynamic simulation of shear-induced particle migration in a two-dimensional circular Couette device [J]. , 2007, 15(3): 333-338.
[15]	WANG Erqiang, LI Chengyue. Simulation of Suspension Catalytic Distillation for Synthesis of Linear Alkylbenzene [J]. , 2003, 11(5): 520-525.